Floating damper assembly

ABSTRACT

A floating damper assembly for applying a constant damping torque to a motor shaft exhibiting substantial runout comprises a flexible cable element, which is anchored at its ends to the motor housing, and a floating damper, which is attached to the cable element substantially at the element&#39;&#39;s center, further including an appropriately shaped bushing of frictional material and means for radially loading the bushing against the shaft. The floating damper assembly is particularly useful in an incremental stepping motor whose step profile must remain relatively constant and free of excessive ringing or overshoot.

United States Patent Leifer et al.

[ 51 May 30, 1972 [54] FLOATING DAMPER ASSENIBLY [72] Inventors: Noel Arlhur'Leifer, Pine Brook; Eugene Charles Schramm, Mountain Lakes, both of NJ.

[73] Assignee: Bell Telephone Laboratories, Incorporated,

Murray Hill, NJ.

22 Filed: Dec. 28, 1970 21 Appl.No.: 101,476

[52] U.S.Cl ..188/1 B, l88/83,3l0/51 [51] Int. Cl ..Fl6l 7/06 [58] Field olSearch ..74/574;188/1B,83;3l0/5l; 336/100; 415/1 19 [56] References Cited UNITED STATES PATENTS 2,655,049 10/1953 Cole ..l88/1BX FOREIGN PATENTS OR APPLICATIONS 502,286 7/1930 Germany ..188/l B Carlstedt 188/1 B X Primary Examiner-Duane A. Reger Att0rneyR. J. Guenther and Kenneth B. Hamlin [57] ABSTRACT A floating damper assembly for applying a constant damping torque to a motor shaft exhibiting substantial runout comprises a flexible cable element, which is anchored at its ends to the motor housing, and a floating damper, which is attached to the cable element substantially at the element's center, further including an appropriately shaped bushing of frictional material and means for radially loading the bushing against the shaft. The floating damper assembly is particularly useful in an incremental stepping motor whose step profile must remain relatively constant and free of excessive ringing or overshoot.

5 Claims, 2 Drawing Figures Patented May 30, 1972 3,666,057

INVENTORS N. ALE/FER By [.CSCHRAMM AT TOPNEV FLOATING DAMPER ASSEMBLY I FIELD OF THE INVENTION This inventionrelates to torsional vibration damping devices and in particular to such devices which apply a constant damping torque to the motor shaft exhibiting substantial runout.

BACKGROUND OF THE INVENTION Devices for damping torsional vibrations of a shaft are well known in the art. However, many such prior art devices are hard mounted to a frame or housing, thereby exhibiting, in the presence of shaft runout (departure from trueness or concentricity), undesirable variations in the frictional damping torque as a. function of the shafts angular displacement.

Torsional vibration damping devices find particular application in incremental stepping motors whose shafts tend to oscillate around positions of rest. Such shaft oscillations result from the moments of inertia of the shaft and of the driven parts; therefore, the shaft does not immediately come to a standstill but oscillates for some time around the nominal position of rest. These oscillations disadvantageously affect the step profile of the incremental stepping motor.

It is therefore an object of this invention to provide a torsional vibration damping device which exhibits a substantially constant damping torque independently of angular displace- SUMMARY or THE INVENTION According to the present invention, a floating damper assembly for damping torsional vibrations of a shaft comprises a flexible cable element, which is anchored at its ends, anda floating damper, which is attached to the cable element substantially at the elements center. A substantially constant damping torque is thereby applied to the shaft.

According to an illustrative embodiment of the invention, a floating damper assembly for damping torsional vibrations of a motor shaft comprises a flexible cable element, which is anchored at its ends to the motor housing, and a floating damper, which is attached to the cable element substantially at the elements center, further including a split carbon bushing and means for spring loading'the bushing against the motor shaft. 1

It is an advantage of this invention that it comprises relatively few parts and thus is easy to assemble.

It is a feature of this invention that it simultaneously provides translational displacement flexibility and rigid tangential restraint.

DESCRIPTION OF THE DRAWING The above and other objects, advantages and features of this invention will be better appreciated by a consideration of the following detailed description and the drawing in which:

FIG. 1 is a partially fragmentary front view of a floating damper assembly according to the present invention; and

FIG. 2 is a partially fragmentary side view of the floating damper assembly of FIG. 1 illustrating how the assembly is anchored to the motor housing and showing the oppositely sensed helical grooves on the motor shaft.

DETAILED DESCRIPTION FIG. 1 is a front view of a floating damper assembly according to the present invention, In the given case, floating damper assembly is utilized to damp the torsional vibrations of shaft 12, which is part of motor 10. Motor 10, which could be an incremental stepping motor, further comprises housing 11.

Assembly 15 comprises cable element 20 and floating damper 30. Cable element 20 simultaneously provides translational displacement flexibility in a direction perpendicular to its axis and rigid tensional restraint along its axis. Cylindrical anchors 21, anchor screws 22, and set screws 23 rigidly fix the ends of cable element 20 to housing 11. FIG. 2 shows in detail how screws 22 attach anchors 21 to housing 1 1.

The length and diameter of cable element 20, and the nominal tension therein, are determined by the particular application.

Floating damper 30 fiirther comprises two-segment housing 31 and split carbon bushing 35 wherein segments 31a and 31b are respectively associated with bushings 35a and 35b. Bushing 35, which is advantageously made of carbon but can be any appropriately shaped frictional material, substantially surroundsshaft 12. Stud 32 and its associated retaining ring 33 secure segments 31a and 31b. It should be noted that segments 31a and 31b can rotate relative to each other, stud 32 being the center of rotation. In addition, set screw 34 attaches segment 31a of housing 31 to cable element 20 substantially at the center of the element. Note that stud 32 has no direct connection to housing 1 l, as is more apparent from FIG. 2.

It has been found advantageous to provide oppositely sensed helical grooves 13 on the part of shaft 12 which is in contact with carbon bushing 35 for carrying away carbon residue particles that result from wear.

Floating damper 30 additionally comprises means for radially loading bushing 35 against shaft 12 including threaded stud 36 and resilient means such as circular coil spring 37. It is apparent that the radial force applied by bushing 35 to shaft 12 is increased by further threading stud 36 into section 31a of housing 31, since the compressive force within spring 37 simultaneously increases. The net radial force applied to shaft 12 by carbon bushing 35 results in a net retarding frictional torque on shaft 12. Therefore, any oscillatory energy imparted to shaft 12 is clamped by this retarding frictional torque. Note that any desired frictional torque can easily be selected during the process of assembly. The adjustability of the spring compression has the further advantage that subsequent regulation of the frictional torque after a period of operation is possible in case such appears necessary.

It is apparent that mechanical fastening means other than those heretofore mentioned can be utilized to assemble the floating damper assembly according to the present invention.

As mentioned before, the step profile of an incremental stepping motor should remain relatively constant and free of excessive ringing or overshoot. It should also be recalled that prior art torsional vibration damping devices exhibit undesirable variations in the frictional damping torque when motor shaft runout is present. However, according to the present invention, by mounting floating damper 30 on cable element 20, considerable vertical translational displacement flexibility is provided by cable element 20 to floating damper 30. Cable element 20 additionally provides tensional restraint which reacts to the frictional damping torque applied by bushing 35 to shaft 12. It is therefore apparent that the usual detrimental effects resulting from shaft runout are overcome by the trans lational displacement flexibility afforded floating damper 30. In conclusion, the floating damper assembly of the present invention is particularly useful in incremental stepping motors for controlling the step profile, even in the presence of substantial shaft runout.

While the arrangement according to this invention for applying a constant damping torque to a rotating shaft has been described in terms of a specific illustrative embodiment, it will be apparent to one skilled in the art that many modifications are possible within the spirit and scope of the disclosed principle.

What is claimed is:

1. A device for applying a constant damping torque to a shaft exhibiting substantial runout, said device comprising:

a flexible cable element rigidly anchored at its ends such that a perpendicular line through the center of said cable element passes through the nominal center of rotation of residue particles resulting from wear of said carbon bushing. said shaft, and 5. A floating damper assembly for applying a constant a floating damper attached to said cable element substandamping torque to a motor shaft exhibiting substantial runout tially at the element's center for applying a constant comprising: damping torque to said shaft. 5 a flexible cable element rigidly anchored at its ends to the 2. The device of claim 1 wherein aid floating dam motor housing such thataperpendicular line through the further comprises an appropriately h d b hi f f i center of said cable element passes through the nominal tional material and means for radially loading said bushing center ofl'otallon Ofsald Shaft. and against said shaft. a floating damper attached to said cable element substan- 3. The device of claim 2 wherein said loading means is an tiany the elemenfs center for pp y g a Constant adjustable spring loading means for selecting the desired dampm$ torque to sal'd F damping OI-qua I said floating damper including an appropriately shaped 4. The device of claim 3 wherein said bushing is a carbon busllmg 'Q 'f means for adlusmbly bushing andsaid shaft contains oppositely sensed helical loadmg said bushmg agamst motor shafi' grooves in contact with said carbon bushing for carrying away 

1. A device for applying a constant damping torque to a shaft exhibiting substantial runout, said device comprising: a flexible cable element rigidly anchored at its ends such that a perpendicular line through the center of said cable element passes through the nominal center of rotation of said shaft, and a floating damper attached to said cable element substantially at the element''s center for applying a constant damping torque to said shaft.
 2. The device of claim 1 wherein said floating damper further comprises an appropriately shaped bushing of frictional material and means for radially loading said bushing against said shaft.
 3. The device of claim 2 wherein said loading means is an adjustable spring loading means for selecting the desired damping torque.
 4. The device of claim 3 wherein said bushing is a carbon bushing and said shaft contains oppositely sensed helical grooves in contact with said carbon bushing for carrying away residue particles resulting from wear of said carbon bushing.
 5. A floating damper assembly for applying a constant damping torque to a motor shaft exhibiting substantial runout comprising: a flexible cable element rigidly anchored at its ends to the motor housing such that a perpendicular line through the center of said cable element passes through the nominal center of rotation of said shaft, and a floating damper attached to said cable element substantially at the element''s center for applying a constant damping torque to said shaft, said floating damper including an appropriately shaped bushing of frictional material and means for adjustably loading said bushing against said motor shaft. 